Catha edulis, a plant that has amphetamine effects

The chewing of fresh leaves of the khat bush (Catha edulis) is common in certain countries of East Africa and the Arab peninsula, because this material has a stimulating effect. During the last decade, important progress has been made in understanding the pharmacology of this drug. Its actions are mainly due to the alkaloid cathinone, a substance that can be called a natural amphetamine.     

Metabolic and neuroanatomical correlates of barrel-rolling and oculoclonic convulsions induced by intraventricular endothelin-1: a novel peptidergic signaling mechanism in visuovestibular and oculomotor regulation?

The neuroactive peptide endothelin-1 has receptors distributed abundantly among subdivisions and nuclei of the visuovestibular and oculomotor systems. In previous work, we and others described the convulsive manifestations resulting from central injection of this neuropeptide, including nystagmus, oculoclonus, exophthalmos, tonic hindlimb extension, and a generalized repetitive motor disturbance called barrel-rolling. We applied the quantitative, autoradiographic [¹⁴C]deoxy-glucose method to examine the hypothesis that visuovestibular and oculomotor structures would become metabolically stimulated when endothelin was introduced into the brain via the ventricular system in conscious rats. Since previous work had demonstrated that hypermetabolic responses to endothelin in other neural systems were inhibited by an antagonist of neuronal calcium L-type channels, nimodipine, we further tested whether the increased function of vestibulooculomotor nuclei whose metabolic activity was sensitive to endothelin could be altered following nimodipine pretreatment via the ventricle. A single unilateral injection of endothelin (9 pmol in 3 l saline) into a lateral ventricle provoked significantly increased rates of glucose metabolism in 22 of 39 individual anatomical structures of the visuovestibular and oculomotor systems. Among those affected were the superficial stratum of the caudal superior colliculus (+25%), the optic tract bilaterally (+ 35 to 43%), the oculomotor cranial nerve nuclei (III, IV, VI; range of +21 to 47%), and the medial terminal nucleus of the accessory optic tract which harbors dense fields of endothelin binding sites (bilateral increase of +70 to 96%). Several other nuclei involved in the proprioceptive and visuovestibular disturbance caused by endothelin displayed increased metabolic activity, including the cuneate, gracile, sensory trigeminal, and prepositus hypoglossal nuclei, the vestibular subnuclear system, and the cerebellar flocculus. Identification of hypermetabolic responsivity to endothelin in these structures provides further information on the anatomical substrates mediating the behavioral phenomenology of endothelin-induced motor convulsions which involve the paroxysmal participation of the extraocular muscles and motor control systems producing barrel-rolling convulsions. Nimodipine pretreatment inhibited both the convulsive activity and the cerebral hypermetabolic responses to intraventricular endothelin. The results indicate that the neural systems sensitive to intraventricular endothelin become functionally active via a calcium-mediated process that may involve the neuropeptide as an intrinsic signaling molecule.     

Circadian rhythm of glucose utilization in the pineal body of rats of different ages

Employing quantitative autoradiography, pineal body glucose utilization (GU) was measured in daytime or at night in prepubertal (aged 1 month), adult (aged 3 months), and mature (over 12 months old) rats. In prepubertal and adult rats, in daytime, GU values within the pineal tissue were homogeneously distributed around 65 mol glucose/100 g per min. In prepubertal animals no significant variations in GU were observed between daytime and nocturnal measurements. A circadian metabolic rhythmicity was evident in adult rats, with a GU peak measured at 2 a.m. In mature animals, GU also varied between day and night, with an increment in the relative difference between the two values. The present investigation is the first to demonstrate that circadian metabolic rhythmicity is absent before sexual maturation while it is enhanced in 12-month-old rats. These changes in pineal energy metabolism with advancing age are intriguing in view of the concept that the pineal gland may be involved in functional changes occurring during the process of aging.     

A soluble androgen receptor in the cytoplasm of the male mastomys prostate

Summary A steroid receptor protein was isolated from the cytoplasmic fraction of Mastomys prostate. Following in vivo and in vitro labelling of the tissue with tritiated testosterone or dihydrotestosterone, samples were analysed by gel exclusion chromatography or sucrose density gradient centrifugation. A steroid receptor complex was isolated on Sephadex G-200. Analysis of the steroids associated with this complex showed that the major part of the bound radioactivity was 5 -dihydrotestosterone. The binding was inhibited by unlabelled testosterone and could not be demonstrated in the liver cytosol. Using sucrose desity gradient centrifugation, the dihydrotestosterone receptor complex sedimented at 5.6 s together with heavier aggregates. In the presence of 0.4 M KCl a single complex was sedimented at 4. 6 s. The results demonstrate a receptor protein in the cytosol of the Mastomys prostate which binds to dihydrotestosterone and is comparable to that of rat prostate.     

Progressive-ratio performance maintained by drug infusions: Comparison of cocaine,diethylpropion, chlorphentermine,and fenfluramine

Cocaine, diethylpropion, chlorphentermine, and fenfluramine were compared on a drug-maintained progressive-ratio procedure in baboons. Intravenous infusions of drug were contingent on completion of a fixed-ratio response requirement (fixed number of lever-press responses) with a 3-h time-out period following each infusion. Prior to testing each dose of drug, stable self-infusion performance was first established with 0.4 mg/kg cocaine when the fixed-ratio requirement was 160. Subsequently, a test dose of drug was substituted for the standard dose of cocaine. If the dose of drug maintained a criterion level of self-infusion performance (six or more infusions per day for 2 days), the ratio requirement was systematically increased every day until the breaking point at which the self-infusion performance fell below a criterion level (one or zero infusionsper day). Fenfluramine did not maintain criterion self-infusion performance at any dose tested (0.02–5.0 mg/kg). The dose ranges of the other drugs that maintained maximum breaking points were 1.0–5.6 mg/kg for chlorphentermine, 1.0–3.0 mg/kg for diethylpropion, and 0.1–0.4 mg/kg for cocaine. Within-animal comparison of the maximum breaking points indicated that cocaine maintained the highest breaking points, followed in order by diethylpropion, chlorphentermine, and fenfluramine. The rank ordering of these drugs with the breaking point measure corresponds well with both the results of other animal experiments on measurement of reinforcing efficacy of these drugs and with the clinical information about the human subjective effects and abuse of these drugs.     

The effect of lithium on amphetamine-induced locomotor stimulation

Rats were treated chronically with -methyl-p-tyrosine methyl-ester HCl (-MT) twice daily for 0–14 days. At 1 h after the (last) -MT injection, d-amphetamine sulphate was given and motor activity was measured in an ANIMEX activity meter for 4 h. Amphetamine-induced excitatory and stereotyped behaviour was scored according to a rating scale in a separate experiment. A single dose of -MT markedly reduced the activity response after amphetamine. After 1–3 days of -MT treatment, tolerance to its amphetamine-antagonistic affect started to develop, reaching a maximal degree after 7–14 days. The pattern of the amphetamine response, monophasic in control rats, became biphasic in the -MT tolerant rats with an early (at 0–1 h) and a late (2–4 h) peak of motor activity. The late peak appeared within 3 days, while the early peak appeared after 7 days of -MT treatment. The results on amphetamine-induced excitatory and stereotyped behaviour in essence agreed with the motor-activity data. It is concluded that tolerance to the amphetamine-antagonistic action of -MT is not complete. Its rate of development varies in a complex pattern, indicating the presence of more than one mechanism of tolerance.     

Hybrid information provided by the 14C-aminopyrine breath test studies with 14C-monomethylaminoantipyrine in the guinea pig

Summary N-Demethylation of ¹⁴C-aminopyrine (¹⁴C-AP), labelled at the methyl groups of the tertiary amino group, yields H¹⁴CHO and ¹⁴C-monomethylaminoantipyrine (¹⁴C-MMAAP) which also undergoes N-demethylation, however, at a slower rate as measured in hepatic microsomes. As after intraperitoneal application to male guinea pigs of ¹⁴C-AP (75 mg/kg; 50 Ci/kg), exhalation rate of ¹⁴CO₂ declines in a biphasic manner, the hypothesis was tested whether the terminal part might reflect N-demethylation of MMAAP. The application of ¹⁴C-MMAAP (70 mg/kg; 10 Ci/kg), resulted in monophasic curves of ¹⁴CO₂ exhalation rate. Their half lives were, however, longer than terminal half lives obtained after ¹⁴C-AP. Obviously, this terminal phase does not represent ¹⁴CO₂ formation from the metabolite MMAAP only, but ¹⁴C-AP might still contribute to ¹⁴CO₂ production. Confirmation was obtained by HPLC determination of AP and MMAAP in serum after injection of AP. Shortly after injection, high concentrations of AP and low ones of MMAAP were found in blood from the portal vein and systemic circulation. Thus, initial parts of ¹⁴CO₂-exhalation rate curves reflect predominantly AP metabolism whereas later phases provide hybrid information.     

β-Adrenoceptor blocking agents as partial agonists in isolated heart muscle: Dissociation of stimulation and blockade

Summary The cardiac stimulant actions of nine -adrenoceptor blocking agents were examined in kitten papillary muscles and in isolated atria of kittens and guinea pigs to determine to what extent these drugs behaved as classical partial agonists. In many ways the agents do appear to comprise a spectrum of partial agonists with widely differing efficacies. However, in one respect the actions of some of the -blockers did not fit into the classical mold. Several -blockers were found to exert stimulant effects only in concentrations appreciably higher than those required for substantial -adrenoceptor blockade. These observations suggest that more than one type of -adrenoceptor may be involved in the production of sympathomimetic effects on cardiac muscle.     

Effects of enkephalins and two enzyme resistant analogues on monoamine synthesis and metabolism in rat brain

Summary Methionine-enkephalin and leucineenkephalin, administered into the lateral ventricle of intact rats, increased the accumulation of DOPA by a naloxone-sensitive mechanism in different brain regions after inhibition of the aromatic l-amino acid decarboxylase. Because of the rapid enzymatic degradation of both enkephalins large doses (500 g) were required to enhance brain catecholamine synthesis. The two enzyme resistant enkephalin analogues d-Ala²-methionine enkephalin amide (DALA (4–256 g) and FK 33-824 (0.003–1 g) also increased the synthesis of DOPA, dose-dependently and by naloxone-sensitive mechanisms, but at much lower dosage level. The enkephalins markedly enhanced the brain tyrosine concentration but this effect was not antagonized by naloxone, probably because the enzymatic cleavage releases tyrosine from the administered peptides. In contrast, neither DALA nor FK 33-824 increased the brain tyrosine concentration. The formation of 5-HTP and the brain tryptophan concentration were also increased by the enkephalins, although these effects were not blocked by naloxone. The enkephalin analogues, however, enhanced the formation of 5-HTP and the brain tryptophan concentration by naloxonesensitive mechanisms. All four peptides accelerated the disappearance of dopamine, noradrenaline and 5-hydroxytryptamine after inhibition of monoamine synthesis. The results suggest that endogenous enkephalins, through the activation of opiate receptors, are involved in the short-term regulation of central monoaminergic systems.Preliminary data were presented at the Nobel Symposium 42, Principles for the Central Regulation of the Endocrine System, Stockholm, June 8–10, 1978, and at the 4th International Catecholamine Symposium, Asilomar Conference Center, Pacific Grove, California, September 17–22, 1978     

Cerebral energy metabolism in patients with brain lesions at normo- and hyperbaric oxygen pressures

Summary The object of this study was to ascertain the oxygen tolerance limit and the oxygenation state of the injured brain in man. While breathing air, oxygen and hyperbaric oxygen at pressures of 1.5 and 2.0 atmospheres absolute (ATA), the cerebral arteriovenous differences (AVD) for O₂, glucose, lactate, pyruvate and blood gas pressures and pH values were measured. The balance of the cerebral glucose metabolism was calculated. The results showed that the injured brain did not tolerate the exposure to an oxygen pressure of 2.0 ATA for 10 to 15 min, but exposure to 1.5 ATA for 35–40 min was tolerated and had a favorable effect on the glucose or energy metabolism of the brain as well as on the clinical course. There was a distinctly increased cerebral glycolysis while breathing air indicating insufficient oxygen delivery to the brain. The change from breathing air to oxygen resulted in a distinct inhibition of cerebral glycolysis, which indicated improved cerebral oxygenation and energy production and gave evidence for a Pasteur effect regulating the glucose metabolism of the injured brain in man. At an inspiratory oxygen pressure of 1.5 ATA we had a nearly balanced cerebral glucose metabolism indicating an adequate cerebral oxygenation and energy formation. Further increase in inspiratory oxygen pressure to 2.0 ATA (performed only in group A) increased cerebral glycolysis considerably. This was assumed to be due to cerebral oxygen poisoning resulting in disturbed oxidative energy formation. Following this alteration an extreme reduction of the cerebral glucose uptake appeared, probably due to a disturbance of the specific glucose transport system. These metabolic alterations were not accompanied by seizures or any other clinical neurological manifestation. In group B, exposed to 1.5 ATA, such alterations of the cerebral glucose metabolism did not appear. A nearly balanced cerebral glucose metabolism was found at inspiratory oxygen pressures of 1.0 and particularly of 1.5 ATA, indicating an improved oxygenation and energy production of the affected brain. Finally, a renewed increase of the cerebral glycolysis occurred following the change from breathing oxygen to air. This again indicated an insufficient oxygen delivery to the affected brain.

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Zusammenfassung Ziel dieser Arbeit war es, die Wirkung verschiedener inspiratorischer O₂-Drucke auf den zerebralen Glukose- bzw. Energiestoffwechsel zu untersuchen. Dabei sollte insbesondere die Sauerstoff-Toleranzgrenze und der Zustand der Oxygenierung des geschädigten Hirns bestimmt werden. Unter Luft-, Sauerstoff und hyperbarer Sauerstoffatmung, d. h. bei Drucken von 1,5 und 2,0 Atmosphären, wurden die arterio-hirnvenösen Differenzen (AVD) für O₂, Glukose, Laktat, Pyruvat sowie die Blutgasdrucke und die pH-Werte gemessen. Die Bilanz des zerebralen Glukosestoffwechsels wurde bestimmt. Die Ergebnisse zeigten vor allem, daß das geschädigte Hirn eine Sauerstoffbelastung von 2,0 Atmosphären mit einer Expositionszeit von 10 bis 15 min nicht toleriert. Dagegen wurde eine Sauerstoffbelastung von 1,5 Atmosphären mit einer Expositionszeit von 35–40 min vertragen und hatte einen günstigen Einfluß auf den zerebralen Glukose- bzw. Energiestoffwechsel sowie auf den Krankheitsverlauf von traumatischen oder ischämischen Hirngewebsveränderungen. Während der Luftatmung fand sich eine erhebliche Steigerung der zerebralen Glykolyse, was auf eine mangelhafte O₂-Versorgung des Hirngewebes hinwies. Der Wechsel von Luft- auf Sauerstoffatmung führte zu einer deutlichen Hemmung der zerebralen Glykolyse. Dies zeigte eine Besserung der zerebralen Sauerstoffversorgung und Energieproduktion an und wies auf einen Pasteur Effekt bei der Regulation des Glukosestoffwechsels des geschädigten Hirns hin. Bei einem inspiratorischen Sauerstoffdruck von 1,5 Atmosphären war eine praktisch ausgeglichene Bilanz des zerebralen Glukosestoffwechsels nachweisbar, was für eine ausreichende Sauerstoffversorgung und Energiebildung des Hirns sprach. Der weitere Anstieg des inspiratorischen Sauerstoffdruckes auf 2,0 Atmosphären, der nur in Gruppe A durchgeführt wurde, bewirkte jedoch eine erhebliche Steigerung der zerebralen Glykolyse. Es ist anzunehmen, daß diese Stoffwechseländerung durch eine zerebrale Sauerstoffvergiftung hervorgerufen wurde, die vor allem zu einer Störung der oxydativen Energiegewinnung führte. Anschließend trat eine extreme Reduzierung der zerebralen Glukoseaufnahme auf, die am ehesten durch eine Störung des spezifischen Glukosetransportsystems des Hirns bedingt war. Diese Stoffwechselstörungen gingen nicht mit epileptischen Anfällen oder sonstigen klinisch-neurologischen Veränderungen einher. Bei den Patienten der Gruppe B, die nur mit einem Sauerstoffdruck von 1,5 Atmosphären belastet wurden, traten derartige Veränderungen des zerebralen Glukosestoffwechsels nicht auf. Eine praktisch ausgeglichene Bilanz des zerebralen Glukosestoffwechsels wurde bei inspiratorischen Sauerstoffdrucken von 1,0 und vor allem von 1,5 Atmosphären nachgewiesen und zeigte eine Besserung der Sauerstoffversorgung und Energiebildung des geschädigten Hirns an. Schließlich beobachteten wir nach dem Wechsel von Sauerstoff- auf Luftatmung einen erneuten Anstieg der zerebralen Glykose, was wiederum auf eine insuffiziente Sauerstoffversorgung des Hirns hinwies.